introduction completion solutions · completion tools technology and manufacturing capacity....

Introduction

01

1-1

Completion Solutions

Introduction

Halliburton offers a wide range of completion products and services designed to maximize well production including subsurface safety systems, high-pressure packer systems, intervention solutions, flow controls, and expandable liner technology as well as intelligent completions and multilateral systems. Our state-of-the-art manufacturing and testing facilities enhance our commitment to providing innovative, value-added completion solutions.

Completion Products

This catalog contains descriptions, illustrations, specifications, and ordering information for Halliburton completion products, including:

» Multilateral completions» Intelligent completions technology» Remote open close technology» Unconventional completions» Openhole isolation systems» Liner hanger systems» Production packers» Isolation barrier valves» Subsurface safety systems» Subsurface flow controls» Straddles and pack-off equipment

Sand Control Solutions and Service Tools catalogs are also available.


1-2

Completion Services

Halliburton completion specialists are highly trained at our world-class training centers and are equipped with the tools to provide the finest and safest pre-job, post-job, and on-site service. The full weight of Halliburton corporate resources lies behind its completion specialists. These resources include innovative research and development, advanced design technology, state-of-the-art testing facilities, and industry-recognized quality assurance programs.

Quality, Health, Safety, and Environment Program

Rather than only focus on a quality system such as ISO 9001, Halliburton has chosen to develop a business system that incorporates quality, health, safety, and environmental (QHSE) requirements in a single management system. The Halliburton Management System (HMS) defines our processes and includes quality, safety, environmental, and occupational health check points.

Health, Safety, and Environmental Policy

Halliburton recognizes the importance of meeting society's needs for health, safety, and protection of the environment. We work proactively with employees, customers, the public, governments, and others to use natural resources in an environmentally sound manner, emphasizing the safety of employees and the public as well as the needs of future generations. We are dedicated to continuous improvement of our global HSE processes, while we supply high-quality products and services to customers. To meet these responsibilities, we manage our business according to the HSE principles.

Training Centers

Halliburton training centers deliver training solutions to grow the competence of our personnel in meeting customer needs. Training can also be acquired at the individual locations around the world through home study, online courses, and on-the-job training.

» Cairo, Egypt» Carrollton, Texas» Duncan, Oklahoma» Ft Worth, Texas» Houston, Texas» Montrose, Scotland» Tronoh, Malaysia» Villahermosa, Mexico

Research, Development, and Engineering

Halliburton provides customers with advanced technology and outstanding personnel to solve problems efficiently and effectively. Research, development, and engineering efforts are conducted at various locations:

» Carrollton Technology Center, Carrollton, Texas» Singapore Technology Center, Singapore» Spring Technology Center, Spring, Texas» Duncan Technology Center, Duncan, Oklahoma» UK Technology Center, Arbroath, Scotland

Global Technology Capabilities

Halliburton Completion Tools technology facilities provide the latest advanced technological equipment available, giving Halliburton comprehensive, in-house environmental testing capabilities for downhole tools. With major engineering facilities in both the Eastern and Western Hemispheres, Halliburton can provide timely delivery of crucial technologies.

Polymer Laboratories

Our polymer laboratories test and evaluate the latest polymeric materials for both surface and downhole applications. Equipment includes a full thermal analysis suite as well as test cells capable of testing seal materials from -40 up to 500°F (260°C) and pressures of up to 40,000 psi (2758 bar). In addition, extensive studies are conducted on the effects of organic amine corrosion inhibitors on elastomers. Halliburton research in seal materials has yielded elastomer compounds unrivaled in the industry.

Metallurgical Laboratories

Mechanical testing and certification performed in the metallurgical laboratories provide analysis and daily support for manufacturing operations. An important function of the metallurgical laboratory is supplying materials recommendations to customers based on individual well data. Heat treatment tests determine whether alloys will function downhole as needed. A scanning electron microscope can examine the surfaceof a failure to determine the cause, whether it be environmental embrittlement, incorrect chemistry,or overstress.

Completion Solutions | Introduction

1-3

Engineering Test Facilities

With a commitment to technology innovation, Halliburton continues to deliver technically superior, value-added products and services. A key component of this process is the state-of-the-art testing and design validation facilities at our various technology centers, which provide:

» Engineering analysis and support» High-temperature/high-pressure testing» Tool qualification to API and ISO requirements

Mike Adams Test Well Facility

As the demand for energy increases, the drilling and completing of wells continues to forge new boundaries. Higher pressures, hotter wells, and tool complexities require state-of-the-art testing facilities. Named in memory of one of our most respected test department leaders, the “Mike Adams” test well is designed to be safe, operationally efficient, and best in class for downhole testing of tools for both vertical and horizontal applications.

The Mike Adams facility is a modern drilling rig that runs on clean, quiet electric power. This big-bore well has a cased hole configured with 20- × 13 3/8- × 9 5/8-in. casing. The 9 5/8-in. casing starts at 5,200 ft (1585 m) and kicks off the vertical bore through a 16°/100-ft (30.5-m) radius into a horizontal section. The facility features an air-conditioned observation room with a safe viewing room for customers, a modern data acquisition system, dressing facilities, and an office area.

Deep Well Simulators

Deep well simulators at the Carrollton, Texas and Singapore Technology Centers are equipped to develop and test completion products under simulated downhole temperatures and pressures, identify potential well control problems, and mitigate risks in field operations. These facilities have the capability to test in simulated conditions up to 700°F (371°C) and hydrostatic pressures up to 30,000 psi (206.8 MPa) in Carrollton and up to 40,000 psi (275.8 MPa) in Singapore.

HA

L377

90

Mike Adams Test Well

Halliburton state-of-the-art research and testing facilities, which include the deep well simulator (shown), accelerate development of new equipment technology already in demand by the petroleum industry.

HA

L177

04


1-4

High-Temperature Test Facilities

Our High-Temperature Gas Test facilities located in Carrollton, Texas, and Singapore are specifically built for testing with liquids or nitrogen gas with a working pressure of 40,000 psi and a maximum of 4 ft³ (0.113 m³) of nitrogen gas. Each facility has vertical test cells designed to accommodate assemblies up to 45-ft (13.72-m) long and 28 in. (711 mm) in diameter, and temperature ranges of 700°F (371°C) to 32°F (0°C). The device undergoing testing receives uniformly heated/cooled air to simulate severe temperatures in a downhole environment. These facilities also have a horizontal bunker rated to the same pressure/volume as the test cells.

High-temperature test facilities are used to test experimental designs for use in high-pressure/high-temperature (HP/HT) wells. The high-temperature test facilities are ideally suited for testing packers per ISO 14310/API 11D for all “V” class ratings. Each test cell is designed to accommodate assemblies up to 30 ft (9.14 m) and 30 in. (762 mm) in diameter and has a temperature range up to 700°F (371°C). The device undergoing testing receives uniformly heated air to simulate severe temperatures downhole.

All of our high-temperature test facilities feature a nitrogen gas system that makes the cell’s sealed/contained atmosphere nonflammable. An oxygen analyzer and alarm system monitors the cell’s atmosphere, and controls are provided to maintain inert mixtures for lower explosion limit control. With these advanced capabilities, Halliburton can accelerate the development of new equipment technology already in demand by the petroleum industry.

Multilateral Test Facility

The multilateral test facility comprises a shop area to prepare long assemblies for testing and a control room to run tests on the 144-ft-long (44-m-long) test beam. The test beam can push up to 200,000 lb, pull 150,000 lb, and stroke in 10-ft (3-m) increments. The shop also houses the TorqueMaster™ Model 8026 unit for assembly makeup and breakout operations. This top-of-the-line facility is equipped with all of the necessary tools so that full assemblies can be tested.

Should a customer want to attend a test, the control room is outfitted with monitors and multiple cameras that monitor the testing area. Additionally, a GoPro® camera is available that can be deployed for close-ups of critical test areas. This testing facility helps ensure that customers receive the high-quality equipment they expect.

TorqueMaster™ is a trademark of National Oilwell Varco.

GoPro® is a registered trademark of GoPro, Inc.

High-Temperature Gas Facility

HA

L378

00

HA

L428

86

Multilateral test facility workshop includes TorqueMaster™ unit, vices, and overhead crane.


1-5

Swell Technology Test Facility

The Swell Technology test facility provides the latest technologies in pressure monitoring, swell rate testing, and fluid compatibility for both full-scale and small-scale tests. Testing can be performed in both static and dynamic temperature environments to replicate downhole conditions accurately. For customer-specific tests, procedures are agreed between Halliburton and the customer before the test unit is built and the test is executed. These procedures contain the specifics of the test, timeline, reporting, and the testing budget. The facility includes digital logging and recording systems to allow customers to evaluate the technology. Remote witnessing of the testing is available upon request.

Singapore Technology and Manufacturing Center

The Completion Technology and Manufacturing Center in Singapore significantly expands the Halliburton Completion Tools technology and manufacturing capacity. Complementing our Carrollton, Texas facility in the Western Hemisphere, the Completion Technology and Manufacturing Center serves as the global headquarters for Completion Tools and allows for the delivery of high-quality products to a broad and growing customer base in the Eastern Hemisphere.

This vast state-of-the-art facility includes manufacturing, technology, and administrative space. Technology laboratories and test facilities house complex processes, such as high-alloy material precision machining, electrode discharge machines, and small deep-hole gun drilling. In addition, deep well simulators, high-pressure/high-temperature testing facilities, and a deep horizontal well enable all aspects of engineering testing and simulated systems integration testing operations.

HA

L426

99

The Swell Technology test facility enhances the design, testing, and qualification of Halliburton Swell Technology and openhole isolation systems.

Singapore Completion Technology and Manufacturing Center

HA

L385

47


1-6

Manufacturing Facilities

Manufacturing facilities for downhole completion equipment are found at the following locations:

» Arbroath, Scotland» Carrollton, Texas» Lafayette, Louisiana» Johor, Malaysia» Singapore» Spring, Texas

Lafayette Manufacturing Center

Located in Lafayette, Louisiana, the 200,000-ft² (18 581-m²) Lafayette Manufacturing Center includes 173,000 ft² (16 072 m²) of manufacturing shop floor space and on-site technology capacity. In addition to the manufacturing shop floor built for long parts, the facility includes a metallurgical laboratory capable of performing physical property tests on incoming raw materials and sample rubber. This state-of-the-art plant features an efficient shop floor layout, new machines, and streamlined processes that allow for maximum productivity. The facility's cutting-edge technology and equipment for screen production includes hydraulic stress-relief racks and machines that help improve the screen jacket assembly process.

Malaysia Manufacturing and Technology Center

The Malaysia Manufacturing and Technology Center manufactures an extensive range of products, including swell and screens technology. The more than 300,000-ft² (27 871-m²) facility includes a manufacturing plant, bulk plant, and an administration building. This site also offers technology capabilities, including high-pressure and physical property tests on location. The Halliburton Malaysia Manufacturing and Technology Center plays a key role in meeting the growing needs of customers in the Eastern Hemisphere and globally.

Malaysia Manufacturing and Technology Center

HA

L250

65


1-7

Technology for Every Challenge

Halliburton meets customer challenges with reliable and economical equipment. Whether the solution requires facing extremes caused by pressure, temperature, environment, economy, or downhole conditions, Halliburton equipment is ready. We offer completion equipment and services for a broad range of applications, including:

» Large monobore completions» Horizontal completions» Multilateral completions» High-pressure/high-temperature (HP/HT) completions» Coiled tubing completions» Deepwater and subsea completions» Shallow completions» Electric submersible pump completions» Conventional single and dual completions» Sand control completions» Intelligent completions

Installations

At Halliburton, our objectives are increasing production and lowering total costs throughout the life cycle of the well. Following are just a few examples of the applications and services Halliburton offers.

Severe-Service Completion Installation

HP/HT packers are designed for the most extreme completion environments. These packers are based on the rugged and reliable Perma-Series® packer and are designed specifically for HP/HT hostile environments. Compatible seal assemblies and various receiving heads, including metal-to-metal latching type are available.

Landing Nipple

Ratch-Latch™Seal AnchorHP/HT Packer

Landing Nipple

Auto-Release Sub

VannGun® Assembly

Severe-Service Completion Installation

HA

L122

773


1-8

Single-String Permanent Packer Completion Installation

This simple, versatile, single-zone completion features, from bottom to top, a wireline re-entry guide. The re-entry guide guides wireline tools that have been run below the end of the tubing string back into the tubing. A bottom no-go landing nipple allows for flowing bottomhole pressure surveys. The selective landing nipple allows the well to be plugged for testing purposes or so tubing can be removed without exposing the formation to kill fluids. A Perma-Series® permanent packer, a sealbore extension below the packer, and a seal unit assembly with locator isolate the upper permanent casing string from the formation and allow tubing expansion or contraction to occur. The sealbore extension can be eliminated and a shorter seal assembly with a latch-type locator can be used if little or no tubing movement is expected. The circulating device allows for selective tubing-to-casing communication. A tubing-retrievable or wireline-retrievable safety valve can also be used.

HydraulicControl Line

Flow Coupling

Tubing-RetrievableSafety Valve

Flow Coupling

Flow Coupling

Sliding Side-Door®

Circulating Device

Locator

Flow Coupling

Seal Unitsand Accessories

Perma-Series®

Permanent Packer

Sealbore Extension

Millout Extension

Adapter

Tubing Joint orPup Joint

Landing Nipple

PerforatedPup Joint

No-Go Landing Nipple

Wireline Re-EntryGuide

Single-String Permanent Packer Completion Installation

HA

L122

776


1-9

Single-String Retrievable Packer Completion Installation

When dealing with sensitive formations, it can be advantageous to lubricate a retrievable production packer into the wellbore under pressure. The packer serves as a temporary plug while tubing is being run and completion fluid circulated and then serves as a production packer. The Halliburton Versa-Set® packer is ideal for these applications. The Versa-Set packer is available in wireline-set or mechanical-set versions. The wireline-set version is set with a standard wireline setting tool or DPU®

downhole power unit with wireline adapter kit. Using a standard on-off tool, the packer can be run with a plug installed at the top of the packer. Once set on wireline, the packer operates as a standard mechanical doublegrip with an on-off tool. It is used for testing, injection, and zone stimulation and can serve as a production packer, temporary bridge plug, or tubing anchor in a pumping application. The packer releases with a 1/4 turn right-hand release.

XL On-Off Toolwith Integral Nipple Profile

Retrievable Packer

No-Go Nipple

Re-Entry Guide

Single-String Retrievable Packer Completion Installation

HA

L122

772


1-10

Dual-String Retrievable Packer Completion Installation

This dual-zone, dual-string completion uses an upper hydraulic-set retrievable dual packer and a lower permanent packer. The permanent packer and tailpipe are run first and set on tubing or wireline. The dual strings and dual hydraulic-set packer are then run with a seal assembly on the bottom of the long string. Once the dual strings are landed and spaced out at the surface, a ball is dropped or a plug is set in the landing nipple below the packer in the short string. Pressure is applied to the short string and sets the dual packer. If a ball catcher is used, increased pressure causes the collet catcher to release, allowing the ball to drop out the end of the tubing. Circulation of completion fluids is achieved using the Sliding Side-Door® circulating device above and below the dual packer.

HydraulicControl Line

Flow Coupling

Safety Valve Landing Nipple

Otis® X® Lock Mandrel

Wireline-RetrievableSafety ValveFlow Coupling

Sliding Side-Door®

Circulating Device

Flow Coupling

Retrievable Hydraulic-SetDual Packer

Otis X Landing Nipple

Collet Catcher Sub

Otis XN® No-Go Landing Nipple

Blast Joint

Sliding Side-DoorCirculating Device

Polished Nipple

Permanent Wireline-SetPerma-Series® Packer

Perforated Pup Joint

Otis X Landing Nipple

Otis XN No-Go Landing Nipple

Wireline Re-Entry Guide

Dual-String Retrievable Packer Completion Installation

HA

L122

770


1-11

Coiled Tubing Completion Installation

Coiled tubing can be used in place of regular jointed production tubing in certain completions. Using coiled tubing allows for reduced completion/decompletion time while using standard completion equipment accessories. Special connectors allow standard completion components to be attached to the coiled tubing. GO™ or HGO mechanical utility packers can be used as an alternative tubing hanger to suspend coiled tubing in siphon string applications.

Shallow Completion Installation

A simple completion is illustrated for shallow applications using a Guiberson® G-6 packer and splined travel joint. A tension-set packer is normally used in shallow applications because weight is not available to set compression-set packers. This particular completion is used in steam injection applications. When replacing the travel joint with an overshot tubing seal divider, the completion is typical of shallow CO2 or water injection applications.

Coiled Tubing Connector

Subsurface Safety ValveAssembly

Side-Pocket Mandrel




Packer Assembly

Seal Assembly

Coiled TubingCompletion Installation

HA

L122

774

Splined Travel Joint

Guiberson®

G-6 Tension Packer

Shallow Completion Installation(Steam, CO2, or Water Injection)

HA

L122

771


1-12

Electric Submersible Pump Completion Installation

One schematic (left) shows an electric submersible pump (ESP) completion that allows annulus gas below the packer to vent to the annulus above the packer. A single hydraulic control line can operate the tubing-retrievable safety valve and annulus gas vent valve.

The other schematic (right) shows an ESP completion that allows for flow control without heavy kill fluids during remedial operations. A downhole master valve is run with a packer,on-off tool, and wireline lock. The valve holds pressure in both directions. It closes when the hydrostatic pressure exceeds a preset value and opens when hydrostatic pressure is reduced.

Electric PowerCable

Cable Clamp

ElectricSubmersiblePump

DownholeMaster Valve

Guiberson® G-6RetrievablePacker

Tubing- RetrievableSafety Valve

ElectricPowerCable

ESP CablePenetrator

ESP Packer

Y-Block

ElectricSubmersible

Pump

Annular Vent Valve

SlidingSide-Door®

Circlulating Sleeve

Landing Nippleand Plug(Packer Setting)

Landing Nippleand Plug

Electric Submersible Pump (ESP)Completion Installation

HA

L122

775

HA

L122

779


1-13

Tubing-Conveyed Perforating Completion Installation

Many types of Halliburton packers are used in completions with tubing-conveyed perforating (TCP) guns, including Versa-Trieve® retrievable packers, Perma-Series® permanent packers, and others. TCP guns can be run as tailpipe connected to the bottom of the packer or through the bore of a set packer. This installation shows a Versa-Trieve packer set on electric wireline. The TCP guns are spaced out below the seal assembly, and the tubing is run in the hole. Before stabbing through the packer, light fluids can be circulated down the tubing to provide an underbalanced situation. The tree is installed and the guns are mechanically or hydraulically fired and released to open the tubing end.

Flow Coupling

Otis® R® Landing Nipple

Flow Coupling

Flow Coupling

Sliding Side-Door®

Circulating Device

Flow Coupling

Seal Assembly

Versa-Trieve®

Packer

Sealbore Extension

Tubing-Conveyed Perforating (TCP) Completion Installation

HA

L122

778


1-14

Multilateral Technology

Multilateral systems help provide cost savings through increased reservoir exposure. The systems are available in a variety of designs and are the most innovative and reliable in the industry. Multilateral systems can be deployed in new or existing wells and are compatible with advanced sand control, fracturing, and SmartWell® completion system technology.

Multilateral wells can have many different completions strategies. In the most simplistic design, openhole laterals are drilled from the cased hole parent bore into a single reservoir where production is commingled. In other instances, the openhole lateral sections are drilled into separate reservoirs, which require flow segregation. If lateral borehole stability is a concern, perforated liners or screens can be dropped into the openhole lateral section. In either scenario, standard Halliburton completion components can be installed in the parent bore for lateral flow control and/or isolation.

FloRite® Segregated Completion Level 5 Through-Tubing Access Both Bores

HA

L390

39

RetrievableDual-BorePacker

Main Bore Tubingwith Short-SealAssembly

FloRite® Dual-BoreDeflector

Lateral BoreTubing withLong-Seal Assembly(Sheathed)

Latch Coupling

Main Bore Tubingwith Short-SealAssembly

PermanentSingle-BorePacker

Landing Nipple

RetrievableSingle-BorePacker

Lateral LowerSealbore Extension

Landing Nipple

WirelineRe-Entry Guide

Production Tubing

RetrievableDual-BorePacker

Production Tubing

HA

L403

32


1-15

AV Annulus Safety Valve

The AV annulus safety valve is a fully retrievable high-performance annulus safety system packer with integral annulus safety valve. The system provides annular bypass through a hydraulically operated poppet valve. The AV system is run in a single trip in conjunction with a setting sub that can be shifted for hydraulic-tubing set or can be alternatively control-line set from surface.

ApplicationsThe AV system is used for the control of annulus fluids in gas lift applications for the monitoring of annulus pressures in critical situations and in one- or two-trip annulus safety system completions. The completion can be run to depth and set with the surface tubing hanger flanged up.

It can also be used in completions in which spacing out against a subsurface tubing hanger is required (i.e., no elastomeric expansion joint is necessary). The tailpipe can be left in either tension or compression. It can be used where high tensile loads and pressure differentials exist with the completion anchored in unsupported or poor-condition casing.

SP™ Tubing-RetrievableSafety Valve

Model AVAnnulus Safety System

Model CS2Communication Sub

Side-PocketGas Lift Mandrel

Model HP2 Control-Line SetRetrievable Production Packeror Model HP1Tubing-Set RetrievableProduction Packer

Model FS Fill Sub

Model PSPacker Setting Anvil® Plugor Model DP1 Anvil Plug

AnnulusSafety System

HA

L122

777


1-16

Isolation Barrier Valves in Dual-Zone Stacked FracPac™ Completion

When retention of wellbore fluids to minimize formation damage is crucial to the success of deepwater sand control projects, integration of the Halliburton remote opening FS2 and mechanical IB4 fluid loss isolation barrier valve technology facilitates this requirement. Using the FS2 and IB4 valves in this stacked FracPac™ application allows sequential isolation of the respective zones immediately after installation and zonal treatments. The inclusion of the dual-line hydraulic LV4 isolation barrier valve within the upper completion design provides a second fully testable bi-directional barrier for wellhead installation once the upper completion is installed.

The FS2, IB4, and LV4 isolation barrier valve designs feature a high-performance ball-closure mechanism that provides a bi-directional seal.

The lower zone completion is installed and fully isolated post-frac pack using a mechanical IB4 isolation barrier valve, which is closed when the collet shifting tool attached to the inner string locates the IB4 shifting profile. This in turn closes the valve when the inner string is retrieved from the well.

The upper zone completion is then installed, incorporating a remote-opening FS2 isolation barrier valve. A collet shifter attached to the bottom of the upper zone completion locates in the shifting profile of the lower zone IB4 valve, opening the valve before setting the upper zone gravel pack packer. The upper zone packer is then set and subsequent FracPac treatments concluded. The FS2 valve closure is completed when the collet shifting tool attached to the inner string locates the FS2 shifting profile, which in turn closes the valve when the inner string is retrieved from the well.

With all zones now isolated with a remote-opening, fully testable bi-directional barrier, the upper completion can be safely and cost-effectively deployed.

The upper completion includes an LV4 isolation barrier valve. When used in conjunction with the FS2 valve installed in the sandface completion, these isolation barrier valves can facilitate wellhead installation.

Once wellhead operations are complete and production is required, the LV4 valve is hydraulically opened, and the FS2 valve is remotely opened by applying a predetermined number of hydraulic cycles, resulting in significant rig time savings.

LV4 Lubricator Valve


HHC Packer

Gravel Pack Packer

MCS Closing Sleeve

FS2 Fluid LossIsolation Barrier Valve

Screens

Mechanical Fluid LossIsolation Barrier Valve

Gravel Pack Packer

MCS Closing Sleeve

Screens

Sump Packer

Dual-Zone Stacked FracPac™ Completion

with Additional Isolation Barrier Valve

HA

L122

767


1-17

Isolation Barrier Valves in Triple-Zone Stacked FracPac™ Completion

Integration of the Halliburton remote-opening FS2 and stepped bore IB5 isolation barrier valve technology helps facilitate wellbore fluid retention to minimize formation damage in deepwater sand control projects. FS2 and IB5 isolation barrier valve designs incorporate a high-performance ball-closure mechanism that provides a bi-directional seal. When used in a stacked FracPac™ application, these valves allow sequential isolation of the respective zones immediately after installation and zonal treatments and also provide unrestricted full-bore access to all three zones once production is required.

The lower zone completion is installed and fully isolated post-frac pack using a stepped bore IB5 valve, which is closed when the collet shifting tool attached to the inner string locates the lower shifting profile of the IB5 valve. This in turn closes the valve when the inner string is retrieved from the well. A second larger collet, which will optimize the production ID, is attached to the bottom of the middle zone completion. This second larger collet will locate in the upper profile of the stepped bore IB5 valve, opening it before the middle zone gravel pack packer is set.

The middle zone is completed in the same manner as the lower zone.

Finally, the upper zone is completed with a remote-opening FS2 valve. The FS2 valve is then fully closed, isolating all three zones after frac packing when the collet shifting tool attached to the inner string locates the shifting profile. This in turn closes the valve when the inner string is retrieved from the well, facilitating upper completion deployment.

The FS2 valve can be remotely opened when production is required, resulting in significant rig time savings.

HHC Packer

Gravel Pack Packer

MCS Closing Sleeve

FS2 Fluid Loss Valve

Gravel Pack Packer

MCS Closing Sleeve

Stepped Bore Collet ShifterStepped Bore IB5Mechanical Fluid Loss Valve

Gravel Pack Packer

MCS Closing Sleeve

Stepped Bore Collet Shifter

Stepped Bore IB5Mechanical Fluid Loss Valve

Sump Packer

HA

L122

768

Triple-Zone Stacked FracPac™ Completion with Isolation

Barrier Valves


1-18

Electric Submersible Pump Completion with Mechanical Reservoir Isolation

Operators can negate escalating rig cost concerns in electric submersible pump (ESP) applications using the Halliburton mechanical IB4 fluid loss isolation barrier valve. In an ESP completion, the IB4 valve helps eliminate costly intervention or well kill operations previously required to perform a workover.

The IB4 valve incorporates a high-performance ball-closure mechanism that provides a bi-directional seal and facilitates the initial isolation of the reservoir immediately after the lower completion installation. Additionally, the IB4 valve provides infinite reservoir isolation/re-entry during upper ESP completion workover operations.

The lower completion is installed with a mechanical IB4 valve. The IB4 valve is closed after the zonal treatment by locating in the shifting profile of the valve upon inner string retrieval with a collet shifting tool. The lower zone is now fully isolated with a testable bi-directional barrier.

The upper completion consisting of a bi-directional collet shifter, isolation seal assembly, and ESP can now be installed. The bi-directional collet shifter attached to the bottom of the upper ESP completion locates in the shifting profile of the IB4 valve, opening it fully prior to the upper completion landing out. The isolation seal assembly directly above the collet shifter stings into the gravel pack packer sealbore extension before mechanical opening of the IB4 valve, providing annulus isolation before re-entry to the reservoir.

In the event of an upper ESP workover, by simply pulling the upper ESP completion, the bi-directional collet shifter locates in the shifting profile of the IB4 valve to fully close it, providing a fully testable bi-directional barrier for workover purposes.

Electric SubmersiblePump

Gravel Pack Packer

MCS Closing Sleeve

IB4 Mechanical Fluid LossIsolation Barrier Valve

Sand Screens

Bi-Directional ColletShifter

Sump Packer

Electric Submersible Pump (ESP) Completion with Mechanical

Reservoir Isolation

HA

L122

769


1-19

LV4 Isolation Barrier Valve in Extended-Reach Perforating Operations

As well paths become more complex and larger sections of reservoir are exposed, the need to perform well interventions during the life of the well to maintain performance should be considered during well planning. Incorporating the Halliburton hydraulic LV4 isolation barrier valve enables operators to deploy long intervention strings without killing the well.

The LV4 valve design incorporates a high-performance ball-closure mechanism that provides a bi-directional seal. Traditionally, well intervention string lengths are limited to the length of lubricator that can be stacked on top of the production tree. The addition of an LV4 valve extends these possibilities by placing the swab valve within the tubing string below the production tree. This delivers operational cost savings and helps improve safety by reducing the number of surface rig ups and intervention trips necessary.

The LV4 valve is normally installed in tandem with the tubing-retrievable safety valve (TRSV) to provide a fully testable bi-directional well barrier for intervention purposes. Positioned above the TRSV, the LV4 valve provides a barrier for lubrication purposes, and when used in conjunction with the TRSV, protects the closure mechanism from damage in the event a toolstring is dropped. The dual control-line balanced actuation piston used to function the LV4 valve allows for unlimited setting depths, making it suitable for use anywhere within the wellbore. The ID through the LV4 valve maintains full access to the TRSV ID, helping ensure full functionality of both tools during the life of the well.

LV4 Lubricator Valve


HHC Packer

Extended LengthPerforating Guns

LV4 Isolation Barrier Valve Included inExtended-Reach Perforating Operation

HAL122782


1-20

Deepwater Completion Installation

As water depths and distance from shore increase and completions become more intricate, the solution to the many challenges of deepwater oil and gas development is to find new efficiencies, particularly when under intensified budget pressures. Deepwater completions can present a range of technical and operating challenges, from well planning to flow management to selecting and installing the appropriate lower and upper completion technologies. A properly designed completion helps achieve a successful end to the drilling process and is vital to ultimate reservoir recovery, field life, and the economic performance of the asset.

Halliburton has an extensive track-record in deepwater plays worldwide, with the basin knowledge and reservoir expertise to help you overcome your greatest deepwater challenges. Our goals are higher ultimate recovery, minimum environmental impact, a shorter time to first production, and the lowest cost-per-foot reservoir delivery.

VersaFlex®

Expandable Liner Hanger

CheckStream®

Chemical InjectionMandrel

DepthStar®


DataSphere ROC™ Permanent DownholePressure Gauge

Perma-Series®

Packer

Long Space-OutTravel Joint

Otis® RPT® Landing Nipple

ESTMZ™Enhanced Single-TripMultizone System

DataSphere® LinX®

Monitoring System

Deepwater Completion Installation

HAL122783


1-21

Multizone Sand Control Systems

Multizone sand control completion systems are proven to save valuable rig time. With a portfolio based on more than 20 years of experience, Halliburton has a long, successful history with single-trip multizone sand control systems.

» Save days of rig time over stacked sand control systems

» Capture short, low-reserve intervals that would normally be bypassed

» Reduce risk by helping eliminate running and retrieving packer plugs

Versa-Trieve® VDHX Packer

MCS Closing Sleeve

PetroGuard® Mesh Modular Screen

Mid-Joint Production Sleeve

PetroGuard Mesh Modular Screen

Frac Circulation Sleeve

X-Trieve™ HPS Retrievable Packer

MCS Closing Sleeve

PetroGuard Mesh Modular Screen

HA

L121809

Multizone Sand Control Completion System


1-22

SmartWell® Completion System Installation

SmartWell® completion systems offer oil and gas producers a systems approach for completing a well to provide active management of the reservoir. Through continuous readout data acquisition and remote control,

the operator can monitor and control flow from or injection into multiple zones within real time. Producers can reconfigure well architecture at will and acquire real-time data without well intervention.

Chemical Injection

Splice Subs

Permanent Downhole Gauges

ZonalIsolation

Connectors

Flow Control

Control Lines

HAL33109SmartWell® Completion System Installation


1-23

DataSphere® Permanent Monitoring Installation

The DataSphere® permanent monitoring suite encompasses the full line of permanent monitoring systems available from Halliburton. The modularity and compatibility of these tools enables customized monitoring solutions to provide superior performance and enhanced reservoir monitoring capabilities.

The suite delivers real-time pressure, temperature, flow, and density information from the wellbore, while helping optimize production and validating reservoir models.

DataSphere ROC™ Permanent Downhole Gauge

DataSphereArray System

DataSphere® FloStream™ Flowmeter

DataSphere® Permanent Monitoring Installation


1-24

Recent Technical Papers on Completion Technology

Number Description

SPE-175437-PAStudy of Multilateral-Well-Construction Reliability. 2017. Ben Butler, Andreas Grossmann, Joe

Parlin, and Chet Sekhon, Halliburton.

SPE-AFRC-2554270-MS

Well Design and Successful Field Installation of Openhole Sand Control Completions with Acid

Stimulation in a Highly Deviated Well in Vietnam. 2016. Hung Vu, Son Tran, and Trang Nguyen,

Lam Son JOC; Bharathwaj Kannan, Khoa Tran, and Thong Nguyen, Halliburton.

SPE-183210-MSMaximizing Completion Efficiency Using Remotely Operated Barrier Valves. 2016. Barry Thomson

and Zac Suresh Arackakudiyil, Halliburton; James Todd, Chevron.

SPE-183035-MSCase Study on Remotely Operated Intelligent Plugs to Eliminate Multiple Wireline Runs in Offshore Completions. 2016. Zac Arackakudiyil Suresh, Linh Nguyen, and Bharathwaj Kannan, Halliburton;

Oh Huyn Jung, Yi Jae Seok, and Truyen Luu, KNOC.

SPE-183489-MSFirst Expandable Liner Hanger Installation in United Arab Emirates in 4HP/HT Well. 2016. Eric Ragsdale, Zeid Mohamed, and Rami Samir ElSin, Halliburton; JC Monneyron and Christophe Roy,

Total Abu Al Bukoosh.

IBP1120_16Water Management: Ways to Reduce Costs. 2016. Mauro Nunes, Marcelo Carrara, and Rubio Leonardo, Halliburton.

SPE-181144-MSDesign of Autonomous Inflow Control Device Completions in Heavy Oil for Complex Reservoir

Structures. 2016. Kim Thornton, Halliburton.

SPE-181660-MS

A Case Study of Open and Cased Hole Well Completions in More than 400 Wells in On-Shore Block

in India. 2016. Nishant Panigrahi, Avinash Bohra, Ashish Ranjan, Satish Nekkanti, and Abhishek

Kumar, Cairn India Ltd; Ashish Kestwal, Ankit Vaibhav, Himanshu Jain, and Animesh Kumar,

Halliburton.

SPE-180304-MSMetal-to-Metal Sealing and Anchoring Expandable Hanger in Gulf of Mexico: Development,

Collaboration, and Execution. 2016. Odee Dagle, James Johnson, and Daniel Moeller, Halliburton.

SPE-181070-MSA Case Study on Remotely Operated Intelligent Bridge Plugs for Plug and Abandonment Operations. 2016. Zac Suresh Arackakudiyil, Barry Thomson, and Carl Henning Førde, Halliburton.

SPE-180578-MS

Investigating the Benefits of Rotating Liner Cementing and Impact Factors. 2016. Quek Khang Song,

Hao Wang, and Weicun Dong, Halliburton; Roger Bradshaw, Wei Cui, and Johnson Njoku, ConocoPhillips Inc.

SPE-180645-MS

Case History: Development of Expandable Liner Hanger for use in New Heavy Wall Casing Design

in Gulf of Mexico. 2016. Luis A. Carrillo, Juan C. Gomez, and Alberto R. Rivera, Pemex; Yovanny Figueroa and Paulo C. Torres, Halliburton; D. De Clute-Melancon, formerly Halliburton.

Evaluation of Effects of Trapped Fluid on Downhole Tool Deformation. 2016. Allan Zhong,

Halliburton.

OTC-27203-MSThe Future State of Completions for the Lower Tertiary in the Gulf of Mexico. 2016. Bruce

Techentien, Stephen Ingram, and Andreas Grossmann, Halliburton.

OTC-27149-MSDissolving Metal vs. Dissolving Plastic in Downhole Hydraulic Fracturing Applications. 2016. Zachary Walton, Michael Fripp, and Matt Merron, Halliburton.

OTC-26674-MS

Well Completion Design Integrity Evaluation Including Thermal and Stress Analysis for Complex

Well Completions Offshore. 2016. A. Chakraborty and A.B. Asba Madzidah, Petronas Carigali Sdn. Bhd.; N. Shahreyar and D. Finley, Halliburton.

OTC-26386-MS

Single-Trip Multizone Sand-Control System Deployed on Hydraulic Workover Unit in Offshore

Malaysia. 2016. Izura Aripin, Teuku Faisalluddin, and M Shahril Majid Allapitchai, PETRONAS Carigali Sdn Bhd; Hudzaifah Zol Hamidy, Ikmal Hakim Ghazali, Ahmad Syauki Ab Latif, Kesavan

Govinathan, and Oktaf Priatna, Halliburton Energy Services.

OTC-26816-MSElectrohydraulic ICV Control System: A Novel Approach to Multizonal Control. 2016. Elias Garcia and Savio Saldanha, Halliburton.

OTC-26736-MS

Remotely Operated Barrier Valve Provides Interventionless Solution for Offshore Vietnam

Completion Campaign. 2016. Bruce McLeod, Halliburton; Nghi Nguyen Chinh, Thang Long Joint Operating Company.

OTC-26659-MS

A Streamlined Product Development Process for Permanent Downhole Gauge: Key to High

Operational Reliability in HPHT Wells. 2016. Aswin Balasubramanian, James Flygare, and Pankaj Shrivastava, Halliburton; Callum Smith, Martin Buchan, and Roy Quaden, Shell.


1-25

SPE-179054-MS

Shiftable Multistage Fracture Completion System Allows for More Options While Increasing

Efficiency and Reducing Wellbore Interactions. 2016. C.T. Krupala, D.A. Young, and M.J. Merron,

Halliburton.

SPE-178174-MS

Computations of Perforating Shock on an Intelligent Completions Interval Control Valve with Test

Validation. 2016. Kevin Harive, Jonathon Joubran, Zachary Butler, Jim Wight, and Gerald Craddock,

Halliburton.

SPE-178159-MS

Overcoming Open Hole Multistage Acid Fracturing Challenges in Saudi Arabian Carbonate

Reservoirs with Swellable Packers, Best Practices and Dynamic Evaluation. 2016. Ataur R. Malik,

Jairo A. Leal, Mohammed A. Asiri, and Tolulope M. Ogundare, Saudi Aramco; Eduardo Soriano, Roberto Vega, and Alfredo Lopez, Halliburton.

SPE-178168-MSDelivering Selective Interval Control: Electro-Hydraulic Intelligent Completion Enhances Reservoir

Management for Multilateral Well. 2016. Elias Garcia and Manesh Mathew, Halliburton.

SPE-177955-MS

Auto-Gas Lift and Smart Well Completion Challenges to Extend Well Life and Running Toward Cost

Effective Program, Field Case Study. 2015. Abdalla Elbarbary, Gehad Mahmoud, Abdulraman

Bahrom, and Mohamed El Gebaly, ADCO; Zeid Mohamed and Alex Kurian Halliburton; Abdul Raman Bin Bahrom, Mohamed Qassem Hussain, and Ali Kshada, ADCO.

SPE-176876-MS

New Toe Sleeve Enables True Casing-Pressure Test in an Eagle Ford Shale Well: A Case Study.

2015. Ben Wellhoefer, Sean Canning, and Travis Alkek, Halliburton; Garner Haydell and Molly Wharton Smith, Murphy Exploration.

SPE-177295-MSRefracturing Early Marcellus Producers Accesses Additional Gas. 2015. Gary Rodvelt, Halliburton;

Mian Ahmad and Austin Blake, CONSOL Energy.

SPE-176745-MSAdvancing Multidisciplinary Training and Development for Young Professionals in the Oil and Gas Industry. 2015. Eric Holderby and Mark Van Domelen, Halliburton.

SPE-174856-MS

A Case Study of Using Expandable Liner Hangers and Advanced Cementation Techniques for ERD

Wells in India. 2015. Monali Lobo, Ashish Singhal, Clifford Lang, Jayabrata Kolay, Pankaj Sinha, Ravi Kant, Roy Varghese, and Sunil Doodraj, Cairn India Ltd.; Jason Li, Animesh Kumar, Ashish

Kestwal, and Ankit Vaibhav, Halliburton Offshore Services Inc.

SPE-176752-MS

Autonomous Inflow Control Devices (AICD): Application in Horizontal Wells Completions in Rubiales Area, Heavy Oil Reservoir. 2015. Max Gomez, A. Florez Anaya, Y. E. Araujo, W. Parra, M.

Uzcategui, and V. Bolaños, Pacific Rubiales Energy Corp.; E. Mayorga, Halliburton; F. A. Porturas,

Ziebel AS.

SPE-175522-MS

Intelligent Completions Customized to Meet the Challenges of Malaysia Reservoirs: Work Flow and

Case Histories. 2015. Rahim Masoudi, Keng Seng Chan, Hooman Karkooti, Sumit Soni, and Shlok

Jalan, Petronas; Noman Shahreyar, Tejas Kalyani, and Douglas Finley, Halliburton.

SPE-174702-MS

Workflow Application for Advanced Well Completions to Meet IOR/EOR Challenges in Malaysia.

2015. Rahim Masoudi, Keng Seng Chan, Hooman Karkooti, Sumit Soni, and Shlok Jalan,

PETRONAS; Noman Shahreyar, Tejas Kalyani, and Douglas Finley, Halliburton.

TEC-366

Deployment Challenges and Performance of New Autonomous Inflow Control Device (AICD)

Completion Technology in Rubiales Field’s Heavy Oil Environment – A Case Study. 2015. Edgar

Alberto Mayorga Cespedes and Robgly Urdaneta, Halliburton; Max Gomez Gualdron, and Alberto Florez, Pacific Rubiales.

SPE-174263-MS

Customized Sealants for Water/Gas Shutoff Operations in Horizontal and Highly Deviated Wellbore

Completions. 2015. Larry Eoff, Julio Vasquez, and Antonio Recio, Halliburton; B.R. Reddy and Natalie Pascarella, formerly of Halliburton.

OTC-25998-MSFirst Usage of an Effective Device for Landing the Production Tubing in Subsea/Deep Water Wells in

Malaysia. 2015. Dan Taylor, Dave Thomson, Benjamin Ong, and Tom Roane, Halliburton.

OTC-26018-MS

Improving Operation Safety of Multi Zone Single Trip Gravel Pack: Holistic Approach to Minimize

Well Control Risk in Mahakam. 2015. B. Muryanto, F. Lavoix, C. Labeyrie, and R. Wijaya, Total E&P;

Y. Ji, T. Roane, H. Hustache, P. Ayusta, and E. Albertson, Halliburton.

SPE-173053-MSCasing Wear Factors: How do They Improve Well Integrity Analyses? 2015. Aniket Kumar and

Robello Samuel, Halliburton.

SPE-173500-MSVeterans Diversity Group Launches Mission: Camouflage to Coveralls. 2015. Lamar Duhon, Anthony E. Wright, David L. Perkins, J. Ryan Petty, Chris J. White, Michelle P. Cox, and Ron

Crawford, Halliburton.


Number Description


1-26

SPE-172565-MS

Optimization of Well Trajectories and Wellhead Towers' Slots Allocation Through a Collaborative

Well-Planning Approach. 2015. Boualem Marir, Christian Mandel, and Ghassan Al Jefri, ADMA-

OPCO; Javier Torres and Salman Ferdian, Halliburton.

SPE-173404-MS

A Small Operator's Implementation of a Digital Oil-Field Initiative. 2015. Frank Eldred and A.S.

Cullick, Linn Energy; Suryansh Purwar, Halliburton; Senthil Arcot, Independent consultant; Chris

Lenzsch, EMC.

IPTC-17897-MSIntelligent Electromechanical Pulling Tool Diagnoses Stuck Crown Plug. 2014. Jack Clemens, Brian

Kempton, and Bryan Kasperski, Halliburton.

SPE-170798-MSMultilateral Level-5 Dual Long Horizontal Openhole Gravel Pack Completion on the Peregrino Field. 2014. Jean-Michel Ranjeva and Espen Dahl, Halliburton Energy Service; Flavio Martinho, Bruno

Goncalves, and Astrid Ramos, Statoil.

FEDSM2014-21600Numerical Investigation of the Flow in a Coaxial Piping System. 2014. Charles Farbos de Luzan, Yuri Perelstein, and Ephraim Gutmark, University of Cincinnati; Thomas Frosell and Frederic Felten,

Halliburton.

SPE-170153-MSApplication of Intelligent Well Technology to a SAGD Producer: Firebag Field Trial. 2014. Richard Michael Stahl and Jennifer D Smith, Suncor Energy Inc.; Scott Hobbs, Halliburton Canada Inc.;

Colin Clarke, Baker Hughes Canada.

SPE-170097-MSScreen-Inflow-Design Considerations with Inflow Control Devices in Heavy Oil. 2014. Onyema Oyeka, Frederic Felten, and Brandon Least, Halliburton.

SPE-172193-MS

Downhole Electrical Disconnect Tool Enables the Parting and Subsequent Re-Connection of the

Upper Completion Containing an ESP from the Lower Intelligent Completion. 2014. Ronaldo Izetti,

Hardy Pinto, and Fabio Rosas, Petrobras; Lorenzzo Minassa, Ravi Vayeda, Benjamin Deyo, Gireesh Bhat, Desiderio Rodrigues, and Antonio Bonfim, Halliburton.

SPE-169202-MS

Expandable Liner Hangers in Off-Bottom Cementing Applications Reduce Cost and Increase

Reliability: Regional Case Histories. 2014. Daniel Hayward, John McCormick, and Marilyn Matice, Halliburton; James Dickinson, consultant.

SPE-168239-MS

A Versatile High-Expansion Hanger Device for Suspension of Downhole Devices during

Performance of Critical Asset Diagnostics and Enhancement Methods. 2014. Ron Zbitowsky and Meflah Al-Murit, Saudi Aramco; Michael Denmon, Scott Gordon, Jacques Babin, and Matthew

Mlcak, Halliburton.

SPE-168271-MSTubing Retrievable Surface Controlled Subsurface Safety Valve Floating Flapper Remediation. 2014. B. Gary, Halliburton; C. Hosli, Shell; A. Luviano, Welltech; J. Langley, Expro Group.

SPE-168238-MS

Next Generation of Battery Operated Electromechanical Setting Tools Increases Reliability at High

Temperatures. 2014. Ron Zbitowsky and Mustafa Al-Buali, Saudi Aramco; Jack Clemens, Michael Denmon, Johnny Dove, and Scott Gordon, Halliburton.

SPE-167782-MS

An Overview of the Completion Challenges in a Tight-Gas Formation in Saudi Arabia. 2014. Jairo

Leal and Jorge Duarte, Saudi Aramco; Eduardo Soriano, Alfredo Lopez, and Damir Fatkhutdinov, Halliburton.

SPE-167171-MS

Modeling, Testing, and Case Histories of Swellable Packer Casing Anchoring Performance Enabled

Wells Destined for Plug and Abandon to Become Producers. 2013. Taylor Stein, Michael Tunstall, and Ben Wellhoefer, Halliburton; C.P. Veillette, Enduring Resources.

SPE-167170-MS

Innovative Pressure-Actuated Toe Sleeve Enables True Casing Pressure Integrity Test and Stage

Fracturing While Improving Completion Economics in Unconventional Resources. 2013. Sean Canning, Kendall Pacey, and Ben Wellhoefer, Halliburton.

OTC-24452-MSNew Completion Process Improves Efficiency For Stimulation of Multi-Zone Carbonate Reservoirs

Offshore. 2013. Sean Canning, Benjamin Wellhoefer, and Matt Howell, Halliburton.

OTC-24268-MSWell Completion Experiences With Autonomous Inflow Control Devices in Latin America. 2013.

Francisco Porturas, Halliburton, Brazil.

SPE-SAS-650

High Expansion Technology Provides Greater Flexibility and Economy When Installing Temporary Downhole Gauges and Samplers. 2013. Jacques Babin, Mike Denmon, and Scott Gordon,

Halliburton; Ron Zbitowsky, Saudi Aramco; Clem Whitmire, Halliburton; Meflah Al-Murit, Saudi

Aramco.


Number Description


1-27

OTC-24371-MS

World's First Installation of an Electro-Hydraulic Disconnect Tool Offshore Brazil. 2013. Ronaldo

Goncalves Izetti, Petrobras; Ravi Vayeda, Halliburton; Hardy Leonardo Pinto, Petrobras; Antonio

Bonfim, Halliburton; F. Rego Rosas, Petrobras; Lorennzzo B. Minassa, Marcelo A. Pavanelli Batocchio, Benjamin Edward Deyo, and Martin L. Staelens, Halliburton.

SPE-165899-MS

Six Zone Intelligent Completion Installation Benefits and Lessons Learned Before Production in

Offshore Indonesia. 2013. Sanjay Jugdaw and Alan Mclauchlan, Halliburton; John C. Leith, ConocoPhillips; Rajat Dave, Halliburton.

SPE-166158-MS

A Milestone in Production Optimization in the Niger Delta Using Intelligent Completions. 2013.

Chinwe Caroline Uchendu, Erasmus John Nnanna, Obaro Amos Okpokpor, Ibrahim Yahaya, and Friday Otutu, Shell Petroleum Dev Nigeria (SPDC); Courage Osasuyi Erumwunse, Halliburton

Nigeria Ltd.; Cardinal Friday Agbonaye, Halliburton Energy Services Group.

SPE-166271-MSA Case Study Using A Remotely Controlled Downhole Valve For Completion Installation. 2013. Keith Oddie, Red Spider Technology Ltd.; John Patrick O'Hara, WellDynamics; Luis Paz, Hess

Corporation.

SPE-166499-MSDesign Methodology for Swellable Elastomer Packers for Well Construction Operations. 2013. Rutger Evers, Halliburton Energy Services Grp; Tom Rune Koloy, Halliburton Worldwide Ltd.; Terje

Abrahamsen, Halliburton A/S.

SPE-166657-MSCase History: First Intelligent Well with Feed-Through Zonal Isolation in a Multilateral Sidetrack Completion in the Troll Field. 2013. Bjorn Olave Dahle, previously with Statoil; Leon Jerome

Prebeau-Menezes, Statoil ASA; Peter E Smith and Geir Gjelstad, Halliburton.

OTC-24169-MS

Large Bore Expandable Liner Hanger provides Reliable, Cost-Effective Solution for Liner Placement

in Critical Well Path. 2013. Michael (Rick) Johnson, Halliburton Energy Services Group; Kevin Wendell Ardoin, Halliburton; Miles Norman Sweep, Chevron ETC; Nathan Barrett Wyatt,

Halliburton Energy Services Grp; Paul Benet, Chevron.

OTC-24197-MSSwellable Technology Seals Top of Liner in Small Annular Area in Deepwater Gulf of Mexico. 2013. Taylor Stein, Halliburton; Ron Hinkie, Halliburton Energy Services Group; Chris Brinkman, Shell.

SPE-163899-MS

Factors Affecting Effective Millout of Multistage Fracturing Sleeves in Horizontal Wellbores. 2013.

Patrick Arthur Stivers and Silumesii Yuyi, Halliburton; Nick Smith, EF Energy; Benjamin Wellhoefer, Halliburton; Charles Richard Tompkins, EF Energy; Robert Rhodes, Halliburton.

SPE-163410-MS

Large Bore Expandable Liner Hangers for Offshore and Deepwater Applications Reduces Cost and

Increases Reliability: GOM Case History. 2013. John McCormick, Alexis Carter, and Rick Johnson, Halliburton.

SPE-163568-MSExpandable Liner Hanger Milling: North Sea Case Histories. 2013. Thomas Berge, Kim Daniel

Mathisen, and Olav Storebo, Halliburton; Michael Muir, Maersk.

SPE-162852-MS

Unique Solution To Repair Casing Failure in an HT/HP Wellbore Allows for Successful Multistage

Stimulation Treatment in an Unconventional Reservoir. 2012. Benjamin Jon Wellhoefer and Neil

Alan Stegent, Halliburton Energy Services Grp; Karl M. Tunstall, Halliburton Easywell; Christian Patrick Veillette, Enduring Resources; Garrett L. Frazier, Magnum Oil Tools International.

SPE-159307-MS

Intelligent Well Type and Optimum Completion Design in the Complex Multi-Stacked

Compartmentalized and Oil Rim Reservoirs. 2012. Rahim Masoudi, Danny Chong, and Hooman Karkooti, Petronas; Mohamad Othman, Petronas Carigali Sdn Bhd; Keng Seng Chan, Petronas;

Douglas B. Finley, Halliburton.

SPE-159261-MS

Novel Design and Implementation of Kuwait's First Multilateral Well with Inflow Control Device and Inflow Control Valve for Life-Cycle Reservoir Management in High Mobility Reservoir, West Kuwait.

2012. Om Prakash Das, Khalaf Al-Enezi, Muhammad Aslam, Taher El-Gezeeri, and Khalid Ziyab,

Kuwait Oil Company; Steven R. Fipke, Halliburton; Steven Ewens, Halliburton WellDynamics.

SPE-156945-MSTorque and Drag Modeling: Advanced Techniques and Troubleshooting. 2012. John Mccormick,

Halliburton; Gefei Liu, Pegasus Vertex Inc.

GT2012-69119

Rotordynamics of a 105,000 rpm Oil-Free Compressor-Expander for Subsurface Natural Gas Compression and Reinjection. 2012. Aaron M. Rimpel and J. Jeffrey Moore, Southwest Research

Institute; Joseph S. Grieco and Perry C. Shy, Halliburton Energy Services; John M. Klein, Rotor-

Therm, Inc.; Jerry L. Brady, BP Exploration Alaska.

GT2012-69017

Open-Loop Aerodynamic Performance Testing of a 105,000 rpm Oil-Free Compressor-Expander for

Subsurface Natural Gas Compression and Reinjection. 2012. Aaron M. Rimpel, Timothy C. Allison,

and J. Jeffrey Moore, Southwest Research Institute; Joseph S. Grieco, Perry C. Shy, Halliburton Energy Services; John M. Klein, Rotor-Therm, Inc.; Jerry L. Brady, BP Exploration Alaska.


Number Description


1-28

SPE-158856-MS

Big Bore Expandable Liner Hangers for Offshore and Deepwater Applications Reduces Cost and

Increases Reliability: Global Case History. 2012. John Mccormick, Marilyn Matice, and Steve Cramp,

Halliburton.

SPE-153702-MSNew Data Retrieval Application Significantly Improves Asset Management in Digital Oilfields with

Intelligent Completions. 2012. Clifford Allen and Robert Smith, Halliburton WellDynamics Inc.

OTC-23628-MS

Case Study: Optimization in Intervention Monobore Design in Completing Horizontal Gas Producing Wells in Malaysia. 2012. Christopher Elliott, Petronas Carigali Sdn. Bhd.; Mohd Imran

Feroze, Petronas Carigali SB; A.A. Ahmad Mahdzan, Saradah Tirungnanasambandan, and M.

Zarkashi Sulaiman, Petronas Carigali SB; Mahzan Mohammad, Lundin Malaysia Ltd.; Mulyanto Hakim, Total E&P USA, Inc.; M. Afiefe Omar, Petronas Carigali SB; Khairil Faiz Abdul Aziz,

Halliburton; Sanggeetha Paramavathar, Halliburton Energy Services Group.

OTC-23630-MSSlickline-Retrievable Wellhead Plugs and Downhole Plugging System Provides Wellbore Integrity for Extreme HPHT Environments. 2012. Brad Pickle, Halliburton; Tom Swan, Halliburton Energy

Services Group.

SPE-154760-MSUsing a new Intelligent Well Technology Completions Strategy to Increase Thermal EOR Recoveries-SAGD Field Trial. 2012. Mark Bedry, Halliburton; Joel Shaw, WellDynamics.

SPE-153880-MS

Ultradeepwater Riserless Subsea Slickline Intervention From Vessel of Opportunity: Brazilian Case

Study. 2012. Scott Gordon, Halliburton; David Russ Larimore, Halliburton Energy Services Group; Gustavo Cervo, Halliburton; Nivea Boechat, Mark Klein, Martin Buchan, and Colin James Innes

Morris, Shell; Scott Davis, Shell International Exploration and Production Inc.

SPE-154421-MS

Slickline-Conveyed Electromechanical Tool Utilization in Deepwater Gulf of Mexico. 2012. Benjamin

Paul Gary, Halliburton Energy Services; Jill Schlechtweg, Shell Exploration & Production; Jack Clemens, Halliburton Energy Services Group; Johnnie Garrett, Shell.

SPE-161564-MS

Innovative Rigless Application to Reinstate Surface Control of Downhole Safety Valve System and

Restore Well Integrity (Case Study). 2012. Saleh Al Braiki, ZADCO Petroleum Co; Obadah Saleem Al-Sawadi and Muhammad Afzal, Zakum Development Co.; Nadir M.M. Odeh, ZADCO Petroleum

Co; Naeem Shahid Yar Khan, Zakum Development Co.; Abdulla Hasan Al Hosani, ZADCO

Petroleum Co; Ahmed Bani Malek, ZADCO; Anwar Yousef, Halliburton Co.; Shamim Faruqi, Halliburton.

SPE-162471-MS

Optimization of Inflow Control Devices or Mechanical Conformance Decisions Using a New

Coupled Well-Intervention Simulator. 2012. Kim V. Thornton, Halliburton Energy Services Group; Mohamed Y. Soliman, Texas Tech University; Ricardo Alberto Jorquera, Halliburton Energy

Services Group.

SPE-159307-MS

Intelligent Well Type and Optimum Completion Design in the Complex Multi-Stacked Compartmentalized and Oil Rim Reservoirs. 2012. Rahim Masoudi, Danny Chong, and Hooman

Karkooti, Petronas; Mohamad Othman, Petronas Carigali Sdn Bhd; Keng Seng Chan, Petronas;

Douglas B. Finley, Halliburton.

SPE-160429-MS

Case History: Innovative Solution Successfully Recompletes Problematic Well in Malaysia. 2012.

Christopher Elliott and Mahzan Mohammad, Petronas Carigali Sdn Bhd; Mohd Imran Feroze,

Petronas Carigali SB; Khairul Azmi Mahadi and Abdil Adzeem Ahmad Mahdzan, Petronas Carigali Sdn Bhd; Khairil Faiz Abdul Aziz and Murray David Forbes, Halliburton; Muhamad Nasri Dzul-Fikar,

Welltec.

SPE-160159-MS

Enhancing the Effectiveness of Long Horizontal Water Injection Wells with ICD/SSD Technology - Design, Simulation and Installation. 2012. Marc D. Kuck, Eni Petroleum Co. Inc.; Luke Holderman,

Halliburton; Dan Brown, Halliburton Co.; Kim V. Thornton, Halliburton Energy Services Group;

Nicholas Kuo, Halliburton.

SPE-160060-MSFirst Intelligent Well Completion in the Troll Field Enables Feed-Through Zonal Isolation: A Case

History. 2012. Bjorn Olav Dahle; Peter Elliot Smith, Geir Gjelstad, and Kristian Solhaug, Halliburton.

SPE-153700-MS

SPE-150850-MS

Second Generation Interval Control Valve (ICV) Improves Operational Efficiency and Inflow Performance in Intelligent Completions. 2012. Jameel U. Rahman and Clifford Allen, Halliburton

WellDynamics; Gireesh Bhat, Halliburton.

SPE-153702-MSNew Data Retrieval Application Significantly Improves Asset Management in Digital Oilfields with Intelligent Completions. 2012. Clifford Allen, Halliburton WellDynamics; Robert Smith,

WellDynamics, Inc.

1302-SCC2012Dynamics of a Completion String in a Fluid Filled Wellbore. 2012. Allan Zhong and Frederic Felten, Halliburton Company.


Number Description


1-29

OTC-23627-MSPacker & Safety Valve Development for Ultra High Pressure High Temperature Test & Production

Wells. 2012. Daniel Martin Taylor, Halliburton Australia Pty Ltd.

SPE-154760-MSSPE-150477-MS

Using a new intelligent Well Technology Completions Strategy to Increase Thermal EOR Recoveries - SAGD Field Trial. 2012. Mark Bedry, Halliburton; Joel Shaw, WellDynamics.

SPE-155202-MS

Combination of Dual String Single Trip Multi-Zone Completion Systems and High Rate Formation

Pack as a Proven Completion Methodology for an Unconsolidated Reservoir: Case Study Tunu Field. 2012. Duncan Laidlaw, Total E&P Indonesie; Mutiara Madyanova, Schlumberger; Daniel Miles

Agee, Dowell Schlumberger; Hugo Hustache, Halliburton.


Number Description


1-30

introduction completion solutions · completion tools technology and manufacturing capacity....

Documents